Aileron Therapeutics Announces Oral Presentation of Non-Clinical Data Demonstrating ALRN-6924 Protected Human Hair Follicles and Their Stem Cells from Chemotherapy-Induced Damage at the European Society for Dermatological Research Annual Meeting 2022

On September 30, 2022 Aileron Therapeutics (Nasdaq: ALRN), a chemoprotection oncology company that aspires to make chemotherapy safer and thereby more effective to save more patients’ lives, reported an oral presentation at the European Society for Dermatological Research (ESDR) Annual Meeting, taking place September 28 – October 1, 2022 in Amsterdam (Press release, Aileron Therapeutics, SEP 30, 2022, View Source [SID1234621585]).

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This presentation includes non-clinical data initially presented at the Society for Investigative Dermatology in May 2022 as well as new non-clinical data developed in collaboration with Professor Ralf Paus, M.D., DSc, FRSB and his colleagues at the Dr. Phillip Frost Department of Dermatology & Cutaneous Surgery at the University of Miami Miller School of Medicine.

Details of the presentation are as follows:

Title: Temporary cell cycle arrest in human scalp hair follicles and their epithelial stem cells by ALRN-6924: A novel strategy to selectively protect p53-wildtype cells against paclitaxel-induced alopecia [Abstract 549]
Presenter: Dr. Ralf Paus; Paus Laboratory, University of Miami Miller School of Medicine
Date: Saturday, October 1, 2022
Time: 12:40 – 12:50 p.m. (local time)
Session: Concurrent session #9: Photobiology and Pigmentation
"Until one is confronted personally with the loss of hair due to chemotherapy, I think it’s difficult to truly understand just how difficult this side effect can be for patients. It is yet another burden layered on top of their already-daunting fight against cancer," said Dr. Paus. "Cold caps, the only FDA-approved treatment for chemotherapy-induced alopecia, are unavailable in many institutions, can cause additional discomfort, and – while often quite useful – are of unpredictable efficacy in a given individual patient. One also cannot help wondering whether scalp micro-metastases might profit from scalp cooling."

Dr. Paus continued, "Based on our hair follicle and scalp skin organ culture work with ALRN-6924, testing two of the most hair loss-inducing chemotherapies, paclitaxel and cyclophosphamide, we’re very encouraged by the potential this drug may hold to prevent alopecia in cancer patients, including for protecting the hair follicle’s sensitive stem cell compartment from permanent damage. We’re particularly excited by ALRN-6924’s highly innovative design, which selectively protects normal cells from the destructive effects of chemotherapy, but – in contrast to any other currently available alopecia-protective strategy – crucially, not the cancer cells."

Aileron is currently developing ALRN-6924, a first-in-class MDM2/MDMX dual inhibitor, to selectively protect healthy cells in patients with cancers that harbor p53 mutations to reduce or eliminate chemotherapy-induced side effects while preserving chemotherapy’s attack on cancer cells. The company is conducting a Phase 1b clinical trial of ALRN-6924 in patients with p53-mutated breast cancer undergoing either neoadjuvant or adjuvant treatment with docetaxel, doxorubicin and cyclophosphamide, also known as TAC. Aileron’s vision is to bring chemoprotection to all patients with p53-mutated cancer regardless of the type of cancer or chemotherapy.

Manuel Aivado, M.D., Ph.D., President and Chief Executive Officer at Aileron, commented, "We’re excited about the results generated by Dr. Paus and his colleagues, particularly given their significant and widely recognized expertise in chemotherapy-induced alopecia. We have amassed a body of strong scientific evidence, including the data being presented at the ESDR meeting, which demonstrate ALRN-6924’s cell cycle arrest mechanism and support its potential to protect against chemotherapy-induced bone marrow toxicities and other toxicities, including alopecia. Collectively, these nonclinical and clinical data have informed the design of our breast cancer trial. We look forward to our anticipated data readouts from that trial later this year and into 2023."

About the Paus et al. Findings

Taxanes, such as paclitaxel and docetaxel, are known to cause severe and often permanent chemotherapy-induced alopecia. Over 90% of patients treated with this chemotherapy class experience alopecia, and approximately 10% (paclitaxel) to 25% (docetaxel) of patients experience permanent alopecia. Cyclophosphamide is also known to cause alopecia: it is commonly co-administered with doxorubicin (Adriamycin) chemotherapy in the "AC" combination, with greater than 90% of patients experiencing hair loss.

Dr. Paus and his team previously demonstrated that paclitaxel damages human scalp hair follicles by inducing massive mitotic defects and apoptosis in hair matrix keratinocytes as well as bulge stem cell DNA damage, and that pharmacological induction of transient cell cycle arrest can protect hair follicles and stem cells (Purba et al. EMBO Molecular Medicine 2019). Aileron previously conducted in vitro studies showing that ALRN-6924 protected human fibroblasts in cell culture from multiple chemotherapies, but not p53-mutant breast cancer cells.

In the non-clinical findings presented at the ESDR and SID meetings, when organ-cultured anagen (i.e., active growth phase) scalp hair follicles from human donors were pre-treated with ALRN-6924 or vehicle (i.e., placebo), followed by paclitaxel or vehicle, ALRN-6924 significantly increased the number of p21-positive hair matrix keratinocytes and bulge stem cells compared to vehicle or paclitaxel alone, confirming cell cycle arrest ex vivo. Further, pretreatment of paclitaxel-treated human hair follicles with ALRN-6924, led to a reduction in the number of melanin clumps, a marker of hair follicle cytotoxicity and dystrophy, as well as a reduction in apoptosis, pathological mitosis, and DNA damage. In new data presented at the ESDR meeting, these assays also yielded positive findings for 4-HC (4-hydroperoxy cyclophosphamide), the active metabolite of cyclophosphamide that is formed in vivo and commonly used for in vitro studies. Aileron believes that these findings support clinical investigation of ALRN-6924’s ability to prevent both acute and permanent chemotherapy-induced alopecia, in addition to its ongoing evaluation of ALRN-6924’s ability to protect against chemotherapy-induced bone marrow and other toxicities.

About Aileron’s Breast Cancer Clinical Trial

Aileron is underway with a Phase 1b, open-label, single-arm, multicenter trial designed to evaluate the safety, tolerability and chemoprotective effect of ALRN-6924 in up to 24 patients with p53-mutated breast cancer undergoing either neoadjuvant or adjuvant treatment with docetaxel, doxorubicin and cyclophosphamide, also known as TAC. The primary endpoints are duration and incidence of severe neutropenia (Grade 4) in cycle 1. Secondary endpoints include the chemoprotective effect of ALRN-6924 on chemotherapy-induced alopecia, as well as other hematologic and non-hematologic toxicities. Planned readouts from the breast cancer trial include data from initial patients in the trial in the fourth quarter of 2022; an interim analysis on 12 patients in the second quarter of 2023; and topline results from 20 patients in the third quarter of 2023.

Corporate Presentation

On September 30, 2022 Alaunos Therapeutics Presented the Corporate Presentation (Presentation, Alaunos Therapeutics, SEP 30, 2022, View Source [SID1234621584]).

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Mandatory notification of trade in connection with grant of options to CEO

On September 30, 2022 EXACT Therapeutics AS ("EXACT-Tx" or the "Company") reported that granted 610,643 share options to the Company’s CEO and primary insider, Per Walday (Press release, Exact Therapeutics, SEP 30, 2022, View Source [SID1234621583]). Each option, when exercised, gives the right to acquire one share in the Company. The shares will be subject to a 12-month lock-up, subject to certain exemptions.

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The share options have a ten (10) year term and vest over a period of 36 months, whereby 25% vest after 12 months, 25% vest after 24 months and 50% vest after 36 months. All options have an exercise price of NOK 15, which is subject to adjustment in the event of i) a change in the share capital, ii) a rights issue or repair issue, or iii) dividends or other distributions in cash or in kind.

Following the grant, Per Walday holds a total of 610,643 share options and 0 shares in the Company.

This information is subject to the disclosure requirements in Regulation EU 596/2014 (MAR) article 19 number 3 and section 5-12 of the Norwegian Securities Trading Act.

Alligator Bioscience Announces Positive Safety Data from 900 mg Dose Cohort in ATOR-1017 Phase 1 Dose Escalation Study in Patients with Advanced Solid Malignancies

On September 30, 2022 Alligator Bioscience (Nasdaq Stockholm: ATORX) reported that positive safety data from the 900 mg dose cohort in its Phase 1, first-in-human clinical trial with the 4-1BB (CD137) targeting drug candidate, ATOR-1017, which is being developed as a tumor-directed therapy for advanced/metastatic cancer (Press release, Alligator Bioscience, SEP 30, 2022, View Source [SID1234621581]).

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The data show that for doses up to 900 mg there were no significant safety concerns with durable stable disease as the best tumor response, confirming previously announced signs of clinical benefit. No dose-limiting toxicity was observed and the maximum tolerated dose (MTD) of ATOR-1017 has not been reached.

The Phase 1 open-label dose-escalation study of ATOR-1017 in patients with histologically confirmed, advanced, and/or refractory solid cancer (NCT04144842) has completed enrollment. The primary objective of the study to investigate the safety and tolerability of ATOR-1017 at therapeutic doses has been successfully met. Two patients remain on the study benefitting from ATOR-1017 treatment.

"We welcome the latest data from the 900 mg dose cohort, the highest dose tested in this trial, which confirm the good safety profile of ATOR-1017," said Søren Bregenholt, PhD, CEO of Alligator Bioscience. "We have observed activation of peripheral T cells and increased levels of soluble 4-1BB across all active dose levels of ATOR-1017, demonstrating biological activity and proof of mechanism, further validating the therapeutic potential of this drug candidate in solid tumors. This Phase 1 study has now succesfully fulfilled its purpose and provides a strong foundation for further clinical development."

The information was submitted for publication, through the agency of the contact person set out below, at 11:00 a.m. CET on September 30, 2022.

Sensei Biotherapeutics Presents Preclinical Data for SNS-101, a Conditionally Active VISTA-blocking Antibody, at the Sixth Annual CRI-ENCI-AACR International Cancer Immunotherapy Conference: Translating Science into Survival

On September 30, 2022 Sensei Biotherapeutics, Inc. (Nasdaq: SNSE), an immuno-oncology company focused on the discovery and development of next-generation therapeutics for cancer, reported that presented additional preclinical data on SNS-101, a monoclonal antibody targeting the immune checkpoint VISTA (V-domain Ig suppressor of T cell activation), at the Sixth Annual CRI-ENCI-AACR International Cancer Immunotherapy Conference (CIMT) (Free CIMT Whitepaper): Translating Science into Survival (Press release, Sensei Biotherapeutics, SEP 30, 2022, View Source [SID1234621580]). The presentation contains data from an ongoing collaboration with scientists at Washington University, St. Louis, investigating the mechanism of action of SNS-101.

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"VISTA remains a promising but difficult-to-drug immuno-oncology target due to significant on-target/off-tumor activity. We’re excited to collaborate with Sensei Bio on studies exploring the efficacy and mechanism of action of their conditionally active, pH-dependent VISTA-blocking antibody, SNS-101," said Robert D. Schreiber, Ph.D., Andrew M. and Jane M. Bursky Distinguished Professor, Pathology & Immunology at the Washington University School of Medicine in St. Louis and a member of Sensei’s Immuno-Oncology Advisory Board. "In our PD-1-resistant, immunocompetent 1956 tumor model, we observed strong synergistic anti-tumor activity of SNS-101 in combination with PD-1 inhibition, resulting in five out of eight complete responses versus only one out of eight in the PD-1 monotherapy control group."

"These preclinical data demonstrate that the selectivity of our conditionally active VISTA-blocking antibody has the potential to avoid poor pharmacokinetics from target-mediated drug disposition and lower the risk of cytokine release syndrome, while significantly enhancing the anti-tumor effects of PD-1 blockade selectively within tumors," said Edward van der Horst, Ph.D., Senior Vice President, Biologics Discovery & Early Development. "These findings support the scientific rationale for Sensei’s pH-selective approach, which we believe could offer numerous safety and efficacy advantages over pH-independent antibodies targeting VISTA, including the potential to inhibit tumor growth across a range of indications."

Summary of Key Data:

SNS-101 potently inhibited the critical pH-dependent interaction between VISTA and PSGL-1, as well as interactions with other putative receptors.
In vitro and in vivo cytokine release syndrome (CRS) assays demonstrate that SNS-101 significantly reduced cytokine induction as compared to a pH-independent VISTA antibody, suggesting that SNS-101 has potential to significantly lower the risk of CRS.
Pharmacokinetics studies demonstrate that the pH-sensitive binding of SNS-101 avoided the rapid clearance by target-mediated drug disposition (TMDD) that has been observed with pH-independent VISTA antibodies.
SNS-101 demonstrated significant enhancement of anti-tumor effects in combination with anti-PD-1 antibodies in multiple syngeneic tumor models.